Bead maker and decorator

ABSTRACT

An apparatus, kit, and method for forming a bead between bead-forming blocks having internal bead-forming channels are provided. The bead-forming channels of adjacent bead-forming blocks are slidably engaged to manipulate a measured amount of modeling compound between the bead-forming blocks and within an internal space between the opposing channels. In one embodiment, the bead-forming blocks maintain orientation with respect to an axis of travel based on a block guide. Further, the measured amount of modeling compound is determined using an integrated measuring feature coupled to at least one of the pair of bead-forming blocks. The internal volume of an integrated measuring feature corresponds to a threshold amount of modeling compound for manipulating between the pair of blocks and forming a bead while contacting at least a portion of the mated bead-forming channels. In further aspects, a molded bead may be coated with a multicomponent bead-coating mixture. Multi-component bead-coating mixtures and methods of using thereof are provided.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority to U.S. Provisional Patent ApplicationNo. 62/252,169, filed Nov. 6, 2015, and entitled, “BEAD MAKER ANDDECORATOR,” the entire contents of which is hereby incorporated byreference. This Non-provisional application is also related toco-pending U.S. Non-provisional application Ser. No. 15/341,853,entitled “BEAD MAKER AND DECORATOR,” filed on the same date as thisapplication.

SUMMARY

Embodiments of the invention are defined by the claims below, not thissummary. This high-level overview of various aspects of the inventionprovides an overview of the disclosure and introduces a selection ofconcepts that are further described in the detailed description sectionbelow. This summary is not intended to identify key features oressential features of the claimed subject matter, and is not intended tobe used as an aid in isolation to determine the scope of the claimedsubject matter.

In brief and at a high level, this disclosure describes, among otherthings, an apparatus, method, and composition for making and decoratingbeads. Embodiments of the invention include a pair of bead-formingblocks, with an upper block having an upper half of a bead-formingchannel and a lower block having a lower half of a bead-forming channel.Block guides and track surfaces on each of the bead-forming blocksengage during contact such that the upper bead-forming channel alignswith the lower bead-forming channel. Further, the block guides ensurethat the bead-forming channel halves remain aligned while the pair ofblocks slide with respect to each other. A measured amount of modelingcompound is positioned between the mated halves of the bead-formingchannel and the transfer of the sliding blocks forms a correspondingshape of a bead within the channel. A multicomponent outer coating maythen be applied to the formed bead by rolling the exterior of the beadin a reservoir of a coating mixture. The outer coating may include agel-like base component and an acrylic coloring component that combinesto provide a marble effect to the surface of the bead.

DESCRIPTION OF THE DRAWINGS

Illustrative embodiments of the invention are described in detail belowwith reference to the attached drawing figures, wherein:

FIG. 1 is a perspective view of an exemplary pair of bead-formingblocks, in accordance with an embodiment of the invention;

FIG. 2 is a perspective view of an exemplary pair of bead-formingblocks, in accordance with an embodiment of the invention;

FIG. 3 is a perspective view of an exemplary pair of bead-formingblocks, in accordance with an embodiment of the invention;

FIG. 4 is a perspective view of an exemplary pair of bead-formingblocks, in accordance with an embodiment of the invention;

FIG. 5 is a perspective view of an exemplary bead-forming block with anamount of modeling compound in the integrated measuring device, inaccordance with an embodiment of the invention;

FIG. 6 is a perspective view of an exemplary bead-forming block with ameasured amount of modeling compound positioned for rolling, inaccordance with an embodiment of the invention;

FIG. 7 is a perspective view of a slidably engaged pair of bead-formingblocks, in accordance with an embodiment of the invention;

FIG. 8 is a perspective view of a bead-forming block revealing a formedbead, in accordance with an embodiment of the invention;

FIG. 9 is an exemplary formed bead with a piercing tool inserted througha portion of the bead, in accordance with an embodiment of theinvention;

FIG. 10 is a perspective view of an exemplary coating mixture trayduring preparation of a multicomponent coating mixture for applying tothe formed bead, in accordance with an embodiment of the invention;

FIG. 11 is a perspective view of an exemplary first pattern of amulticomponent coating mixture applied to a formed bead surface, inaccordance with an embodiment of the invention;

FIG. 12 is a perspective view of an exemplary second pattern of amulticomponent coating mixture applied to a formed bead surface, inaccordance with an embodiment of the invention;

FIG. 13 is a front perspective view of a formed bead having amulticomponent coating mixture applied to the spherical bead surface, inaccordance with an embodiment of the invention;

FIG. 14 is a grouping of multiple formed beads having exterior coatingsof multicomponent coating mixture, as strung together to form abracelet, in accordance with an embodiment of the invention; and

FIG. 15 is an exemplary method for forming a bead with a pair ofbead-forming blocks and decorating the formed bead with an outercoating, in accordance with an embodiment of the invention.

DETAILED DESCRIPTION

The subject matter of embodiments of the invention is described withspecificity herein to meet statutory requirements. The descriptionitself is not intended to necessarily limit the scope of claims. Rather,the claimed subject matter might be embodied in other ways to includedifferent steps or combinations of steps similar to the ones describedin this document, in conjunction with other present or futuretechnologies. Terms should not be interpreted as implying any particularorder among or between various steps herein disclosed unless and exceptwhen the order of individual steps is explicitly described.

Embodiments of the invention are directed to an apparatus, method, andcomposition for making and decorating beads. Embodiments of theinvention include a pair of bead-forming blocks, with an upper blockhaving an upper half of a bead-forming channel and a lower block havinga lower half of a bead-forming channel. Block guides and track surfaceson each of the bead-forming blocks engage during contact such that theupper bead-forming channel aligns with the lower bead-forming channel.Further, the block guides ensure that the bead-forming channel halvesremain aligned during sliding of the pair of blocks with respect to eachother. A measured amount of modeling compound is positioned between themated halves of the bead-forming channel and the transfer of the slidingblocks forms a corresponding shape of bead within the channel. Amulticomponent outer coating may then be applied to the formed bead byrolling the exterior of the bead in a reservoir of a coating mixture.The outer coating may include a gel-like base component and an acryliccoloring component that combine to provide a marble effect to thesurface of the bead.

In one embodiment of the invention, a bead-making apparatus is provided.The bead-making apparatus includes a first bead-forming block comprisinga first bead-forming channel along a longitudinal axis of the firstbead-forming block, wherein the first bead-forming channel comprises afirst channel shape and a first channel depth with respect to aninterior surface of the first bead-forming block. The bead-makingapparatus further includes a second bead-forming block corresponding tothe first bead-forming block, the second bead-forming block comprising asecond bead-forming channel along a longitudinal axis of the secondbead-forming block, wherein the second bead-forming channel comprises asecond channel shape and a second channel depth with respect to aninterior surface of the second bead-forming block, wherein the firstchannel shape and the second channel shape are mirror images of eachother. Additionally, the apparatus includes at least one integratedmeasuring feature coupled to one or more of the first bead-forming blockand the second bead-forming block, said integrated measuring featurecomprising an interior volume for measuring an amount of modelingcompound.

In another embodiment of the invention, a bead-forming kit is provided.The kit includes an upper bead-forming block having an interior portioncomprising an upper block guide, a first track surface, an upperbead-forming channel, and a second track surface oriented in a directionof a first axis. The kit further includes a lower bead-forming blockhaving an interior portion comprising a lower block guide, a third tracksurface, a lower bead-forming channel, and a fourth track surfaceoriented in a direction of the first axis. The lower bead-formingchannel corresponds to the upper bead-forming channel, wherein uponslidably engaging the interior portion of the upper bead-forming blockwith the interior portion of the lower bead-forming block, the upperblock guide is adjacent the fourth track surface and the lower blockguide is adjacent the second track surface. In further embodiments, thekit includes an integrated measuring feature coupled to at least one ofthe upper bead-forming block and the lower bead-forming block, saidintegrated measuring feature comprising an internal volume for measuringan amount of modeling compound for forming a bead between the upperbead-forming channel and the lower bead-forming channel.

In a further embodiment, a method for forming a bead between twobead-forming blocks includes: measuring an amount of modeling compoundwith a measuring feature coupled to one of a first guide block and asecond guide block; depositing the measured amount of modeling compoundbetween a first bead-forming channel of the first guide block and asecond bead-forming channel of the second guide block; and translatingan interior surface of the first guide block with respect to an interiorsurface of the second guide block such that the measured amount ofmodeling compound is manipulated between the first bead-forming channeland the second bead-forming channel to provide a molded beadcorresponding to a first channel shape of the first bead-forming channeland a second channel shape of the second bead-forming channel.

With reference initially to the exemplary embodiment of FIG. 1, thebead-making kit 10 may include a pair of bead-forming blocks 12 that areconfigured to slidably engage while forming a bead of modeling materialbetween the pair of blocks 12. The modeling material, such as a modelingcompound, moldable clay, or other pliable material, is formed into asymmetrical bead based on manipulation between the pair of blocks,having a final shape corresponding to the adjacent interior surfaces ofthe neighboring blocks 12. In one embodiment, the exemplary pair ofbead-forming blocks 12 includes a first bead-forming block 14 withfeatures that mirror a second bead-forming block 16. The firstbead-forming block 14 includes a first block guide 18 having a firstblock guide depth 20 based on a spacing between the block guide outeredge 22 and the adjacent first track surface 24. Further, thebead-forming block 14 includes a second track surface 26 arranged in thesame plane as the first track surface 24, which together provide acommon contact surface for engaging with an adjacent second bead-formingblock 16.

Further, the second bead-forming block 16 includes a second block guide19 having a second block guide depth 28, a block guide outer edge 30adjacent a third track surface 32, and a fourth track surface 34. Inembodiments, the third track surface 32 and the fourth track surface 34are arranged in the same plane to provide a common contact surface forengaging with an adjacent block, such as the first bead-forming block14. For example, the pair of blocks 12 may be slidably engaged basedon 1) contact between the first track surface 24 and the fourth tracksurface 34, and 2) contact between the second track surface 26 and thethird track surface 32. As shown in the example of FIG. 1, the firstblock guide 18 and the second block guide 19 may maintain alignmentand/or contact between at least a portion of the opposing track surfaces24/34 and 26/32.

The pair of bead-forming blocks 12 further includes corresponding halvesof a bead-forming channel for creating a molded bead of modeling clay.As shown in the example of FIG. 1, the first bead-forming block 14includes a bead-forming channel 36 that coordinates with the opposingbead-forming channel 38 of the second bead-forming block 16. The channelshapes 40 and 42 of the bead-forming channels 36 and 38 are mirrorimages of each other when the interior surface 46 of the firstbead-forming block 14 is facing the interior surface 50 of the secondbead-forming block 16. As such, a user may manipulate the exteriorsurfaces 44 and 48 of the respective bead-forming blocks 14 and 16 whileslidably engaging an amount of modeling compound between the opposingbead-forming channels 36 and 38 in a direction along the x-axis.

In one embodiment of the invention, an integrated measuring feature 52and 56 may be provided in association with one or both of the pair ofbead-forming blocks 12. An interior volume 54 and 58 of the integratedmeasuring features 52 and 56 correspond to a volume of modeling compoundfor manipulation by the particular pair of bead-forming blocks 12, suchas the first bead-forming block 14 and the second bead-forming block 16of FIG. 1. For example, an amount of space between the bead-formingchannels 36 and 38 corresponds to a total amount of modeling compoundinside the integrated measuring feature 52 or 56. A user may utilizeeither of the integrated measuring features 52 and 56 for measuring aspecific amount of clay corresponding to the channel space between thebead-forming channels 36 and 38. However, a user may also choose not toutilize either of the integrated measuring features 52 and 56, insteadopting to manually estimate the appropriate amount of clay for insertioninto the corresponding channel space.

In further embodiments, the bead-forming channels 36 and 38 may includea surface feature 64, such as a rough surface, a smooth surface, araised/lowered textured surface, and/or other surface characteristics,for slidably engaging an amount of modeling clay between the adjacentchannels. For example, a contact surface between the adjacentbead-forming channels 36 and 38 may require a minimum amount of tractionfor rolling a bead of a modeling compound between the bead-formingchannels 36 and 38, while maintaining travel of the modeling materialand minimizing spreading of the compound onto the surface of thechannel.

In further aspects, the first bead-forming channel 36 is recessed withrespect to the first track surface 24 and the second track surface 26 ata depth 60 from the interior surface 46. Similarly, the secondbead-forming channel 38 is recessed with respect to the third tracksurface 32 and the fourth track surface 34 at a depth 62 from theinterior surface 50. During manipulation, the first block guide 18 maycontact an outer edge of the fourth track surface 34, while the secondblock guide 19 may contact an outer edge of the second track surface 26.In further aspects, based on contact between the interior surfaces 46and 50, and parallel positioning of the first block guide 18 and thesecond block guide 19, the blocks may remain engaged along the interiorsurfaces 46 and 50, and refrain from shifting with respect to the y-axisor z-axis while sliding along the x-axis.

The exemplary pair of bead-forming blocks 12 in FIG. 2 provides anotherembodiment of a bead-making kit 66. In this example, the interiorsurface 108 on a third bead-forming block 68 faces an interior surface110 of the fourth bead-forming block 70. A user may utilize either ofthe integrated measuring features 98 and 102, coupled to the blocks 12,for measuring a specific amount of clay corresponding to the openchannel space between the bead-forming channels 92 and 94, havingbead-forming channel depths 82 and 90, respectively. In this example,the interior volume 100 of the integrated measuring feature 98 and theinterior volume 104 of the integrated measuring feature 102 eachcorresponds to a measured volume of modeling compound/clay formanipulation between the third bead-forming block 68 and the fourthbead-forming block 70 of FIG. 2. In embodiments, a single integratedmeasuring feature may be provided, coupled to one of the pair of blocks12. In further aspects, where multiple integrated measuring features arecoupled to the pair of blocks 12, each of the integrated measuringfeatures includes an interior volume that satisfies the requisite amountof modeling compound for manipulation between the blocks 12. As such, ameasured amount of modeling compound that fills the interior volume 100or a measured amount of modeling compound that fills the interior volume104 may be used to satisfy the void between both the third bead-formingblock 68 and the fourth bead-forming block 70, as such measured interiorvolume corresponds to the requisite measured amount of modeling compoundfor forming a bead within the open space of the mated bead-formingchannels 92 and 94.

Once the measured amount of modeling compound is positioned between thepair of blocks 12, within the space aligned between bead-formingchannels 92 and 94, a user may manipulate the exterior surfaces 106 and112 of the respective bead-forming blocks 68 and 70 while slidablyengaging the measured amount of modeling compound between the opposingbead-forming channels 92 and 94 in a direction along the x-axis. Inembodiments, the third bead-forming block 68 includes a third blockguide 72 having a block guide outer edge 76, a first track surface 78,and a second track surface 80. Further, the fourth bead-forming block 70includes a fourth block guide 74 having a block guide outer edge 84, athird track surface 86, and a fourth track surface 88. In embodiments,the pair of blocks 12 may slidably engage based on 1) contact betweenthe first track surface 78 and the fourth track surface 88, and 2)contact between the second track surface 80 and the third track surface86.

As shown in the example of FIG. 2, the third block guide 72 and thefourth block guide 74 may maintain alignment and/or contact between atleast a portion of the opposing track surfaces 78/88 and 80/86. In oneaspect, the third block guide 72 is configured to engage with an outeredge of the fourth track surface 88, while the fourth block guide 74 isconfigured to engage an outer edge of the second track surface 80, suchthat the interior surfaces 108 and 110 remain contacted during beadformation and refrain from shifting apart with respect to the y-axis orz-axis while the pair of blocks 12 slide along the x-axis.

Turning next to FIG. 3, an exemplary bead-making kit 114 includes a pairof bead-forming blocks 12 having an upper channel 116 and a channeldepth 128, a lower channel 118 with a channel shape 120 and a channeldepth 126, an upper integrated measuring feature 132 with an interiorvolume 130, and a lower integrated measuring feature 124 with aninterior volume 122. In embodiments, the interior chamber formed betweenthe upper and lower channels 116 and 118, having channel shape 120,provides a specific channel opening for molding a measured amount ofmodeling compound into a particular bead shape. In one aspect, the kit114 includes one or more integrated measuring features, such as one orboth of the integrated measuring features 132 and 124, for determining athreshold amount of modeling compound required to mold a bead using theupper and lower channels 116 and 118. As such, the interior volume 130of the upper integrated measuring feature 132 may be used to measure athreshold amount of modeling compound for molding a bead with the upperand lower channels 116 and 118 of the kit 114. Similarly, the interiorvolume 122 of the lower integrated measuring feature 124 may be used tomeasure a threshold amount of modeling compound for molding a bead withthe kit 114. In some embodiments, integrated measuring features 132 and124 include an interior volume for measuring the requisite amount ofmodeling compound for manipulation between the mated upper and lowerchannels 116 and 118 of the pair of bead-forming blocks 12 in the kit114.

In FIG. 4, an exemplary bead-making kit 134 includes a pair ofbead-forming blocks 12 having an upper channel 142 with a channel shape140 and a channel depth 154, a lower channel 138 with a channel shape136 and a channel depth 152, an upper integrated measuring feature 144with an interior volume 146, and a lower integrated measuring feature148 with an interior volume 150. In embodiments, the interior chamberformed between channel shape 140 and channel shape 136 provides aspecific channel opening for molding a measured amount of modelingcompound into a particular bead shape. In one aspect, the kit 134includes one or more integrated measuring features, such as one or bothof the integrated measuring features 144 and 148, for determining athreshold amount of modeling compound required to mold a bead using theupper and lower channels 142 and 138. As such, the interior volume 146of the upper integrated measuring feature 144 may be used to measure athreshold amount of modeling compound for molding a bead with the upperand lower channels 142 and 138 of the kit 134. Similarly, the interiorvolume 150 of the lower integrated measuring feature 148 may be used tomeasure a threshold amount of modeling compound for molding a bead withthe kit 134. In some embodiments, integrated measuring features 144 and148 include an interior volume for measuring the requisite amount ofmodeling compound for manipulation between the mated upper and lowerchannels 142 and 138 of the pair of bead-forming blocks 12 in the kit134.

As shown in the examples of FIGS. 1-4, a pair of bead-forming blocks 12includes an upper block having an upper bead-forming channel and a lowerblock having a lower bead-forming channel. In embodiments, the upper andlower bead-forming channels have the same internal channel shape, suchas a curved channel shape on an upper bead-forming block that ismirrored by a curved channel shape on the mated lower bead-formingblock. As such, with respect to the interior surface of each block, thechannel depth of upper and lower bead-forming blocks are also consistentbetween pairs of bead-forming blocks. When paired together, the mirroredchannel shape and channel depth of upper and lower bead-forming channelsprovide an internal chamber between the upper and lower channels formolding a particular shape of bead from a threshold amount of modelingcompound.

In some aspects, the threshold amount of modeling compound correspondingto a particular pair of bead-forming blocks (as determined by at leastone integrated measuring feature coupled to at least one block in thepair) is a predetermined volume of modeling compound configured tocontact both the upper and lower channels of a pair of bead-formingblocks when positioned between the mated upper and lower channels. Assuch, based on contacting the internal surface of the mated upper andlower channels, the predetermined volume of modeling compound may beformed into a bead having an exterior that corresponds to the particularchannel shape while the pair of bead-forming blocks are translated backand forth along the x-axis. Additionally, in one embodiment, the lengthof the bead-forming channel may be between about 50 and 70 mm, while inanother embodiment, the bead-forming channel of a pair of bead-formingblocks may be between about 62 and 64 mm long. With such length, thecorresponding width of the channel for providing a particular bead shapemay be between about 8 and 15 mm. For example, a capsule-shaped channelfor producing an oval-shaped bead and/or having a capsule-shapedintegrated measuring feature may include a channel width of about 13 mm,while in another example, a semicircle-shaped channel for producing aspherical bead and/or having a hemisphere-shaped integrated measuringfeature may include a channel width of about 10 mm. In anotherembodiment of the invention, a bead-forming channel may include achannel length of about 17 mm and a channel depth of about 4 mm. Inanother example, a v-shaped (or other shape) bead-forming channel mayinclude a channel width of about 12 mm and a channel side length ofabout 9 mm. The channel shapes discussed in this disclosure are notmeant to be limiting, and any shape or size of the upper and lowerchannels are considered to be within the scope of this disclosure.

The threshold amount of modeling compound measured by an integratedmeasuring feature may be a predetermined volume of modeling compoundwithin a range of requisite modeling compound, such as an integratedmeasuring feature having an interior volume X, with a range of measuredvolume between 0.9× and 1.1× modeling compound, according to someembodiments of the invention. In another embodiment, a predeterminedvolume of modeling compound corresponds to a specific amount of claythat is moveable within the interior chamber formed between the upperand lower channels of a pair of bead-forming blocks. In other words, thepredetermined volume may be measured for each different pair ofbead-forming blocks because each pair of blocks with a different upperand lower channel shape has a different threshold requirement for amoveable amount of clay between paired, sliding blocks having thatparticular channel configuration, such as the channel shape, depth,width, size, surface, etc. Accordingly, embodiments of the bead-formingblocks described herein may be used to produce beads of numerous sizesprovided that the dimensions of the components are suitably scaled. Forexample, if the volume of an integrated measuring feature is increasedto provide a measured volume of a larger bead, the dimensions of thecorresponding bead-forming channels may be increased. Similarly, uponincreasing the measured volume of a larger bead, the dimensions of acorresponding reservoir for applying a coating mixture to the bead maybe increased proportionally to facilitate rolling of the bead andexposure of the increased size of the bead surface. In one aspect, asmaller bead-forming system including a smaller integrated measuringfeature and a smaller set of bead-forming channels may be used togenerate a small-sized bead for coating in a smaller reservoir. Inanother aspect, a larger bead-forming system including a largerintegrated measuring feature and a larger set of bead-forming channelsmay be used to generate a larger-sized bead for coating in a largerreservoir.

As such, according to various embodiments, the proportion, scale, size,dimension, and/or orientation of the bead-forming channels may changebased on a size of bead produced. While a longer and/or deeperbead-forming channel may be used to generate a larger bead, in oneexample, a shorter and/or shallower bead-forming channel may be used togenerate a smaller bead. For example, a kit including multiplebead-forming devices may include differently shaped “scoops” having ahemispherical configuration that is coupled to at least one of thebead-forming blocks to which the scoop volume corresponds. In someaspects, an integrated measuring feature or scoop may include a varietyof shapes while maintaining a particular volume corresponding to aproduced bead. For example, a scoop may have a capsule shaping,elongated in an oval orientation, while in another example, a scoop mayinclude a spherical shaping, having a half-circle appearance. Accordingto one embodiment, a hemisphere-shaped integrated measuring feature mayinclude a volume between about 0.5 to 1.5 cubic centimeters (cm³), whilein another embodiment, the integrated measuring feature may include avolume between about 0.6 and 1.2 cm³. In another embodiment, acapsule-shaped integrated measuring feature may include a volume betweenabout 1.2 and 3.2 cm³, while in further embodiments, the volume may bebetween about 1.5 and 3.0 cm³.

In another aspect of the invention, a reservoir for coating the bead mayinclude a corresponding volume based on the one or more of theintegrated measuring feature volume, the bead-forming channel shape, andthe produced bead size. For example, the reservoir/pan volume may bebetween about 2 to 5 cm³, while in further aspects, the reservoirincludes a cavity having between about 3 and 4 cm³ for holding thecoating mixture, such as a reservoir volume of 3.5 cm³, in someembodiments.

Additionally, the reservoir may include one or more features forsecuring the coating mixture and/or applying it to the formed bead. Forexample, the reservoir may include one or more reservoir sides thatslope inward towards the main volume of the reservoir. Based on avariety of configurations, the bead-coating reservoir may include avariable length, width, and depth. In one example, the reservoirincludes a length and width at an upper portion that tapers to thelength and width of the lower portion based on a sloping of the sides ofthe reservoir. In one example, a reservoir may include a particularopening size and a particular reservoir bottom that provides reservoirdimensions that correlate to the circumference of the bead at its widestportion, such that the bead may be rolled within the reservoir by atleast one complete rotation for coating the entire surface of the beadwith gel and/or paint. For example, the reservoir may include dimensionsbetween about 30 and 35 mm at a top portion, and between about 15 to 20mm at a bottom portion, providing a reservoir for coating a surface of abead with at least one complete rotation of the bead within thereservoir. In another example, the reservoir may include dimensionsbetween about 32 and 34 mm at a top portion of the reservoir opening,and between about 16 to 18 mm at a bottom portion of the reservoir,providing a reservoir volume and shape that accommodates a coating of anentire surface of a particular-sized bead. In other words, the length ofthe reservoir/pan may be at least the circumference of a bead, and infurther embodiments, the length of the reservoir/pan is slightly morethan the circumference of the bead such that a complete rotation of thebead is facilitated (i.e., all surfaces of the bead are coated as it isrolled from one end to the other end of the reservoir).

In one aspect, the reservoir includes a threshold length such that auser will roll the bead without replicating the coating. For example, ifthe reservoir is longer in length that the circumference of the bead, auser may roll the bead longer than necessary to coat each surface of thebead, and may therefore cause smearing and/or blending of the paint/gelcoating. In another example, the depth of the reservoir may be aparticular size to provide for full immersion of the bead withoutrolling, with a reservoir depth corresponding to the bead diameter. Inyet another example, the reservoir depth may facilitate immersion of ahemisphere of the bead surface.

Turning next to FIG. 5, an exemplary bead-forming block 156 includes abead-forming channel 94 oriented with a first end A and a second end Balong the x-axis. Based on the channel shape 96 of the bead-formingchannel 94, the bead-forming block 156 includes an integrated measuringfeature 102 having an internal volume 104 that is used to provide ameasured portion 158 of modeling compound when formed within theintegrated measuring feature 102. In FIG. 6, the measured amount ofmodeling compound 158 having a surface 160 is placed within thebead-forming channel 94. Once paired with the upper bead-forming channelof upper bead-forming block 68 in FIG. 7, the upper and lowerbead-forming blocks 68 and 70 are shifted in a forward and backwarddirection of motion 162, from the first end A to the second end B alongthe x-axis. In some aspects, shifting along the x-axis (i.e., back andforth along the direction of motion 162) displaces the upper and lowerblocks 68 and 70 a first amount 164 with respect to the first end A, anda corresponding second amount 166 with respect to the second end B. Infurther aspects, while maintaining the modeling compound 158 between thetwo blocks, the upper block 68 may be shifted towards the second end Bto displace the second end B of the upper block 68 a first amount 164,and further displace the first end A a second amount 166 with respect tothe lower block 70. Such back and forth manipulation of the paired upperand lower blocks 68 and 70 causes repeated and/or consistent translationof the modeling compound between the blocks during bead formation.

Upon translating the upper and lower blocks multiple times with respectto each other, along the direction of motion 162, the upper block 68 isremoved to reveal the formed bead 168 within the channel of lower block70. In embodiments, the bead formed in FIG. 8 is formed within the matedchannels of the upper and lower blocks, based on a specific amount ofmeasured modeling compound determined using the integrated measuringfeature 102.

Once the measured modeling compound is formed into a bead, as shown inFIG. 9, a piercing tool 172 may be inserted through a portion of theformed bead 168, in accordance with an embodiment of the invention. Oncepierced, the formed bead may be further manipulated, such as having acoating mixture applied to an outer surface of the bead, as furtherdescribed below.

In the exemplary embodiment of FIG. 10, coating mixture components 174may be provided with a bead-forming kit for application of one or morecoloring features to an exterior surface of the formed bead. In oneembodiment, a tray 176 may be used to combine a first bottle 180 of afirst solution 182 with a second bottle 184 of a second solution 186,which may be stirred using a mixing tool 188 to provide a multicomponentcoating mixture 178. In FIG. 11, an exemplary first pattern 190 of amulticomponent coating mixture 178 is applied to the surface of a formedbead 168, in accordance with an embodiment of the invention. Based onthe mixing characteristics of the multicomponent coating mixture 178, apattern of one or more coloring features may be applied to the formedbead 168, such as a first pattern feature C, a second pattern feature D,and a third pattern feature E. In response to further mixing and/orcombining of the multicomponent coating mixture 178, a dispersedmulticomponent coating mixture 178 may produce a blended application 196of the same coloring features, as shown in FIG. 12. As shown in FIG. 13,upon additional application to the outer surface 160 of the formed bead168, a covered bead 198 may be formed, having one or more differentpatterns of coloring application, including fourth pattern feature F,fifth pattern feature G, and sixth pattern feature H on the outersurface 160 of the formed bead 168.

Turning next to FIG. 14, a grouping of multiple formed beads 200 havingexterior coatings of multicomponent coating mixtures are depicted inaccordance with an embodiment of the invention. Each of the shaped beadsin the grouping of multiple formed beads 200 may be formed using aparticular pair of bead-forming blocks, such as the bead-forming blocksdepicted in FIGS. 1-4 discussed above. In one embodiment, a first bead202 may be formed using the pair of bead-forming blocks depicted in FIG.4, having an upper channel 142 and lower channel 138 configured to forma spherical first bead 202. In another embodiment, a second bead 204 maybe formed between the bead-forming blocks of FIG. 2, having an upperchannel 92 and lower channel 94 configured to form a spherical secondbead 204.

In further aspects of the invention, a third bead 206 may be formedbetween the bead-forming blocks of FIG. 1, having an upper channel 36and a lower channel 38 to form an oval third bead 206. In anotheraspect, a fourth bead 208 may be formed between the bead-forming blocksof FIG. 3, having an upper channel 116 and a lower channel 118configured to form a conical fourth bead 208.

Turning next to FIG. 15, an exemplary method 210 for forming a bead witha pair of bead-forming blocks and decorating the formed bead with anouter coating is provided in accordance with an embodiment of theinvention. At block 212, an amount of modeling compound is measured withan integrated measuring feature coupled to a first bead-forming block.Once the modeling compound is measured, at block 214, it is deposited inthe channel formed between the first bead-forming block and a second,corresponding bead-forming block. At block 216, the first bead-formingblock is translated with respect to the second bead-forming block suchthat the measured amount of modeling compound is manipulated within thechannel to provide a molded bead corresponding to the channel shape. Forexample, a conical bead may be formed by a particular shape of matedupper and lower channels on a pair of bead-forming blocks. In anotherexample, a spherical bead may be formed by a particular shape of matedupper and lower channels on a pair of bead-forming blocks. At block 218,an outer coating may be applied to the molded bead, such as themulticomponent coating mixture described above.

In another embodiment of the invention, the multicomponent coatingmixture (or “coating mixture”) is provided. As described herein, thecoating mixture is a liquid that may be applied to a formed bead byrolling the exterior of the bead in a reservoir that contains thecoating mixture. The coating mixture thus forms an outer coating on theformed bead. The coating mixture includes a gel-like base component andone or more acrylic coloring components.

The gel-like base component and acrylic coloring component(s) maycombine to provide a patterned effect on the surface of the bead. Forexample, the patterned effect may be a “marbleized effect,” whereinpatterns created by streaks of color on the bead resemble patterns foundin marble. In certain embodiments, the marbleized effect is madepossible by the heterogeneity of the coating mixture, i.e., the gel-likebase component and acrylic coloring component(s) do not immediatelyblend together to form a homogeneous solution when they are combined.Stated another way, each acrylic coloring component does not immediatelydisperse and become solubilized within the gel-like base component.Instead, the coating mixture is initially heterogeneous after theacrylic coloring component(s) and gel-like base component are combined,whereby each acrylic coloring component resembles a floating “film” inthe gel-like base component. If multiple acrylic coloring components areadded to the gel-like base component, they do not initially mix toprovide a uniform color, but form floating “films” next to one another(with multiple colors visible). The floating films are fluid and may bemoved around within the gel-like base component to form a design, suchas a marbleized design (e.g., by using a mixing tool 188). According toparticular embodiments, the bead is made from a material to which thecoating mixture easily adheres to provide a patterned effect; forexample, the bead may comprise a clay material, as described herein. Amarbleized effect that is created by streaks of color in the coatingmixture can be transferred to the bead.

Embodiments of multiple acrylic coloring components in the gel-like basecomponent are depicted in FIGS. 10 and 11. As described herein, themultiple acrylic coloring components may begin to blend together inresponse to further mixing of the coating mixture; for example, by usinga mixing tool 188 or by rolling the exterior of a bead in the coatingmixture. An embodiment of a coating mixture in which the acryliccoloring components have begun to blend together following mixing isdepicted in FIG. 12.

Embodiments of a marbleized effect are depicted in FIG. 14, in which themulticomponent coating mixtures provide marbleized effects on the formedbeads 200. According to particular embodiments, the multicomponentcoating mixture does not contain any oil-based paints, and thereforedoes not contain any drying oils. In certain embodiments, themulticomponent coating mixture does not contain oil of any kind.

In one embodiment, the gel-like base component comprises, consistsessentially of, or consists of: an aqueous carrier (e.g., water), one ormore water-swellable clay materials, optionally one or morepreservatives, and optionally one or more additives. According toparticular embodiments, the gel-like base component is clear (i.e.,colorless). The gel-like base component may be prepared by mixing theaqueous carrier, the water-swellable clay material(s), the optionalpreservative(s), and the optional additive(s) together until asubstantially homogeneous composition is achieved.

According to particular embodiments, the aqueous carrier included in thegel-like base component is water. Alternatively, the aqueous carrier mayinclude water and optionally one or more water-miscible organic solvents(e.g., one or more solvents selected from the group consisting ofalcohols, glycols, glycol ethers, esters, ketones, and a combinationthereof).

According to particular embodiments, the aqueous carrier is included inthe gel-like base component in an amount between about 85.0 wt % andabout 99.0 wt % (based on the total gel-like base componentcomposition). Alternatively, the aqueous carrier is included in thegel-like base component in an amount between about 87.5 wt % and about99.0 wt %, or between about 90.0 wt % and about 99.0 wt %, or betweenabout 92.5 wt % and about 99.0 wt %, or between about 94.0 wt % andabout 99.0 wt %, or between about 95.0 wt % and about 99.0 wt %, orbetween about 95.5 wt % and about 99.0 wt %, or between about 96.0 wt %and about 99.0 wt %, or between about 87.5 wt % and about 98.5% wt %, orbetween about 90.0 wt % and about 98.5 wt %, or between about 92.5 wt %and about 98.5 wt %, or between about 95.0 wt % and about 98.5 wt %, orbetween about 95.5 wt % and about 98.5 wt %, or between about 96.0 wt %and about 98.5 wt %, or between about 87.5 wt % and about 98.0 wt %, orbetween about 90.0 wt % and about 98.0 wt %, or between about 92.5 wt %and about 98.0 wt %, or between about 95.0 wt % and about 98.0 wt %, orbetween about 95.5 wt % and about 98.0 wt %, or between about 96.0 wt %and about 98.0 wt % (based on the total gel-like base componentcomposition). Alternatively, the aqueous carrier is included in thegel-like base component in an amount of at least about 85.0 wt %, or atleast about 87.5 wt %, or at least about 90.0 wt %, or at least about92.5 wt %, or at least about 95.0 wt %, or at least about 95.5 wt %, orat least about 96.0 wt %, or at least about 96.5 wt %, or at least about97.0 wt % (based on the total gel-like base component composition).

According to particular embodiments, the water-swellable claymaterial(s) included in the gel-like base component are colloidallayered silicates that are manufactured from naturally occurringinorganic mineral sources. “Water-swellable clay materials” are alsoreferred to in the art as “clay thickeners,” “nanoclays,” “syntheticnanoclays,” “water-swellable nanoclays,” and “synthetic layeredsilicates.” Water-swellable clay material swells in an aqueous carrier,such as water, to produce a thixotropic gel (also referred to as acolloidal dispersion). Non-limiting examples of water-swellable claymaterials include water-swellable smectite, water-swellable bentonite,water-swellable mica, water-swellable hectorite, water-swellablemontmorillonite, water-swellable saponite, water-swellable syntheticmica, and combinations thereof. In a specific embodiment, thewater-swellable clay material is a synthetic layered hectorite magnesiumlithium silicate. Exemplary water-swellable clay materials suitable foruse in connection with the present invention are sold under thetradename Laponite® (e.g., Laponite® RD and Laponite® XLS). Laponite® isa synthetic layered hectorite magnesium lithium silicate.

According to particular embodiments, the water-swellable claymaterial(s) are included in the gel-like base component in a totalamount between about 0.1 wt % and about 4.0 wt % (based on the totalgel-like base component composition). Alternatively, the water-swellableclay material(s) are included in the gel-like base component in anamount between about 0.1 wt % and about 3.5 wt %, or between about 0.1wt % and about 3.5 wt %, or between about 0.1 wt % and about 3.0 wt %,or between about 0.1 wt % and about 2.5 wt %, or between about 0.1 wt %and about 2.0 wt %, or between about 0.1 wt % and about 1.5 wt %, orbetween about 0.1 wt % and about 1.0 wt %, or between about 0.5 wt % andabout 4.0 wt %, or between about 0.5 wt % and about 3.5 wt %, or betweenabout 0.5 wt % and about 3.0 wt %, or between about 0.5 wt % and about2.5 wt %, or between about 0.5 wt % and about 2.0 wt %, or between about0.5 wt % and about 1.5 wt %, or between about 0.5 wt % and about 1.0 wt%, or between about 1.0 wt % and about 4.0 wt %, or between about 1.0 wt% and about 3.5 wt %, or between about 1.0 wt % and about 3.0 wt %, orbetween about 1.0 wt % and about 2.5 wt %, or between about 1.0 wt % andabout 2.0 wt %, or between about 1.5 wt % and about 4.0 wt %, or betweenabout 1.5 wt % and about 3.5 wt %, or between about 1.5 wt % and about3.0 wt %, or between about 1.5 wt % and about 2.5 wt %, or between about1.5 wt % and about 2.0 wt % (based on the total gel-like base componentcomposition).

The one or more optional preservatives included in the gel-like basecomponent may be biocides (e.g., anti-bacterial and/or anti-fungalagents). Various commercially-available preservatives that are suitablefor use in the gel-like base component are well-known in the art.Non-limiting examples of preservatives are sold under the tradenamesMergal® and Preventol® (e.g., Mergal® 395 and Preventol® CMK NA).

According to particular embodiments, the optional preservative(s) areincluded in the gel-like base component in a total amount between 0 wt %and about 2.0 wt % (based on the total gel-like base componentcomposition). Alternatively, the optional preservative(s) are includedin the gel-like base component in an amount between about 0 wt % andabout 2.0 wt %, or between 0 wt % and about 1.5 wt %, or between 0 wt %and about 1.0 wt %, or between 0 wt % and about 0.5 wt %, or betweenabout 0.01 wt % and about 2.0 wt %, or between about 0.01 wt % and about1.5 wt %, or between about 0.01 wt % and about 1.0 wt %, or betweenabout 0.01 wt % and about 0.5 wt % (based on the total gel-like basecomponent composition).

The one or more optional additives included in the gel-like basecomponent may be selected from the group consisting of rheologymodifiers, dispersants (e.g., surfactants), pH adjusters, anti-foamingagents, and a combination thereof. Various commercially-availableadditives that are suitable for use in the gel-like base component arewell-known in the art. According to particular embodiments, the optionaladditive(s) are included in the gel-like base component in a totalamount between 0 wt % and about 2.0 wt % (based on the total gel-likebase component composition). Alternatively, the optional additive(s) areincluded in the gel-like base component in an amount between about 0 wt% and about 2.0 wt %, or between 0 wt % and about 1.5 wt %, or between 0wt % and about 1.0 wt %, or between 0 wt % and about 0.5 wt %, orbetween about 0.01 wt % and about 2.0 wt %, or between about 0.01 wt %and about 1.5 wt %, or between about 0.01 wt % and about 1.0 wt %, orbetween about 0.01 wt % and about 0.5 wt % (based on the total gel-likebase component composition).

According to one embodiment, the gel-like base component comprises,consists essentially of, or consists of: an aqueous carrier (e.g.,water) in an amount between about 92.0 wt % and about 99.0 wt %, one ormore water-swellable clay materials in a total amount between about 1.0wt % and about 4.0 wt % (e.g., Laponite® RD and/or Laponite® XLS),optionally one or more preservatives in a total amount between 0 wt %and about 2.0 wt % (e.g., Mergal® 395 and/or Preventol® CMK NA), andoptionally one or more additives in a total amount between 0 wt % andabout 2.0 wt %.

According to another embodiment, the gel-like base component comprises,consists essentially of, or consists of: an aqueous carrier (e.g.,water) in an amount between about 93.0 wt % and about 98.5 wt %, one ormore water-swellable clay materials in a total amount between about 1.5wt % and about 3.0 wt % (e.g., Laponite® RD and/or Laponite® XLS),optionally one or more preservatives in a total amount between 0 wt %and about 2.0 wt % (e.g., Mergal® 395 and/or Preventol® CMK NA), andoptionally one or more additives in a total amount between 0 wt % andabout 2.0 wt %.

According to another embodiment, the gel-like base component comprises,consists essentially of, or consists of: an aqueous carrier (e.g.,water) in an amount between about 96.0 wt % and about 98.0 wt %, one ormore water-swellable clay materials in a total amount between about 1.5wt % and about 2.0 wt % (e.g., Laponite® RD and/or Laponite® XLS), oneor more preservatives in a total amount of between 0.1 wt % and about1.0 wt % (e.g., Mergal® 395 and/or Preventol® CMK NA), and optionallyone or more additives in a total amount of between 0 wt % and about 1.0wt %.

According to an exemplary embodiment, the gel-like base componentcomprises, consists essentially of, or consists of the followingcomponents:

Deionized water—97.06%

Laponite® RD—1.5%

Laponite® XLS—0.44%

Mergal® 395—0.8%

Preventol® CMK NA—0.15%.

According to particular embodiments, the acrylic coloring components(which are combined with the gel-like base component to form the coatingmixture) are liquid acrylic paints, which are commercially available ina wide variety of colors. Acrylic paint typically includes a pigmentsuspension in an acrylic polymer emulsion. In certain embodiments, eachacrylic coloring component is a liquid acrylic paint that comprises,consists essentially of, or consists of an aqueous carrier (e.g., waterand optionally one or more water-miscible organic solvents), one or moreacrylic resins (typically referred to as a “binder”), one or morepigments, and optionally one or more additives (e.g., rheologymodifiers, dispersants, pH adjusters, anti-foaming agents, etc.). Unlikeoil-based paints, which include oil as the vehicle (e.g., linseed oil oranother drying oil), water typically serves as the vehicle forsuspension of the acrylic resin that is the binder in acrylic paint.Thus, oil paint is “oil-based,” whereas acrylic paint is typically“water-based.”

In an embodiment of the invention, a bead-forming kit includes agel-like base component and one or more acrylic coloring components. Thebead-forming kit may also include a bead-making apparatus in accordancewith any of the embodiments described herein. In certain embodiments,the gel-like base component and each of the one or more acrylic coloringcomponents is provided in a separate container. For example, thebead-forming kit may include the gel-like base component inside a firstcontainer, a first acrylic coloring component inside a second container,a second acrylic coloring component inside a third container, a thirdacrylic coloring component inside a fourth container, etc. According toparticular embodiments, each of the acrylic coloring components is adifferent color; for example, the kit may include one or more acryliccoloring components selected from the group consisting of a red acryliccoloring component, an orange acrylic coloring component, a yellowacrylic coloring component, a green acrylic coloring component, a blueacrylic coloring component, a purple acrylic coloring component, a pinkacrylic coloring component, a white acrylic coloring component, a blackacrylic coloring component, a brown acrylic coloring component, and acombination thereof. According to certain embodiments, the kit containsa plurality of the aforementioned acrylic coloring components.

In a further embodiment, a method for forming a bead includes decoratingthe formed bead with an outer coating. Stated another way, the methodincludes applying a multicomponent coating mixture to the surface of thebead (e.g., by rolling the exterior of the bead in a reservoir of themulticomponent coating mixture). The multicomponent coating mixture, andthe resulting outer coating on the bead, include the gel-like basecomponent and the one or more acrylic coloring components. According toparticular embodiments, the method further comprises forming the beadbetween two bead-forming blocks in accordance with any of theembodiments described herein, prior to applying the multicomponentcoating mixture to the outer surface of the bead.

According to particular embodiments, the method for forming a beadincludes mixing the gel-like base component and the one or more acryliccoloring components together (e.g., in a reservoir) to form a coatingmixture, and applying the coating mixture onto the surface of the bead,thereby forming an outer coating on the bead. The outer coating canprovide a patterned effect, such as a marbleized effect, on the bead.The method may further comprise drying the coated bead; for example, byallowing the bead to air dry.

As illustrated in the exemplary embodiment of FIG. 10, mixing thegel-like base component and the acrylic coating component(s) togethermay comprise dispensing an amount of the gel-like base component 182from a first bottle 180 into the reservoir 176, and dispensing an amountof an acrylic coating component 186 from a second bottle 184 into thegel-like base component 182. For example, a user may dispense thegel-like base component into the reservoir, and dispense each desiredacrylic coating component dropwise into the gel-like base component toprovide the multicomponent coating mixture 178. The user may selectwhich acrylic coating component(s) to add to the gel-like basecomponent, based on which color(s) are desired in the coating mixture.The user may also select the amount of each acrylic coating component toadd to the gel-like base component, based on the amount of each colordesired in the coating mixture. A user also has the option of mixing thegel-like base component and the acrylic coating component(s) around inthe reservoir to form a desired pattern or a blended application, forexample, by using a mixing tool 188.

The amounts of gel-like base component and acrylic coating component(s)that are dispensed into the reservoir are not particularly limited.Suitable amounts of gel-like base component and acrylic coatingcomponent(s) depend on the size of the reservoir (i.e., the total volumethat can be contained inside the reservoir) and the size of the bead.According to particular embodiments, the amount of gel-like basecomponent dispensed into the reservoir is sufficient to coat theexterior of a bead by rolling the bead in the reservoir. For example,the amount of gel-like base component dispensed into the reservoir maybe between about 1 ml and about 7 ml, or between about 1 ml and about 5ml, or between about 1 ml and about 3 ml. The acrylic coatingcomponent(s) may be added drop-wise to the gel-like base component inany amount that is preferred by the user. For example, one drop maycomprise between about 0.01 ml and about 0.1 ml, or between about 0.03ml and about 0.08 ml, or between about 0.04 ml and about 0.07 ml, orabout 0.05 ml, of the acrylic coating component; and a user may add anyamount of drops (e.g., between one drop and ten drops, or between onedrop and five drops). The amount of acrylic coating component(s) addedto the gel-like base component is dependent upon the amount and varietyof color that the user wishes to add to the bead.

Many different arrangements of the various components depicted, as wellas components not shown, are possible without departing from the scopeof the claims below. Embodiments of the technology have been describedwith the intent to be illustrative rather than restrictive. Alternativeembodiments will become apparent to readers of this disclosure after andbecause of reading it. Alternative means of implementing theaforementioned can be completed without departing from the scope of theclaims below. Certain features and subcombinations are of utility andmay be employed without reference to other features and subcombinationsand are contemplated within the scope of the claims.

What is claimed is:
 1. A bead-making apparatus comprising: a firstbead-forming block comprising a first bead-forming channel along alongitudinal axis of the first bead-forming block, wherein the firstbead-forming channel comprises a first channel shape and a first channeldepth with respect to an interior surface of the first bead-formingblock; a second bead-forming block corresponding to the firstbead-forming block, the second bead-forming block comprising a secondbead-forming channel along a longitudinal axis of the secondbead-forming block, wherein the second bead-forming channel comprises asecond channel shape and a second channel depth with respect to aninterior surface of the second bead-forming block, wherein the firstchannel shape and the second channel shape are mirror images of eachother; and at least one integrated measuring feature coupled to one ormore of the first bead-forming block and the second bead-forming block,said integrated measuring feature comprising an interior volume formeasuring an amount of modeling compound.
 2. The bead-making apparatusof claim 1, wherein at least a portion of the interior surface of thefirst bead-forming block is configured to slidably couple to at least aportion of the interior surface of the second bead-forming block.
 3. Thebead-making apparatus of claim 1, wherein an internal cavity is formedalong the longitudinal axis between the first bead-forming channel andthe second bead-forming channel, said internal cavity comprising a firsthalf corresponding to the first channel shape and the first channeldepth, and a second half corresponding to the second channel shape andthe second channel depth.
 4. The bead-making apparatus of claim 1,wherein at least one of the first bead-forming block and the secondbead-forming block comprises a block guide.
 5. The bead-making apparatusof claim 1, wherein the interior surface of the first bead-forming blockcomprises a first track surface and a second track surface on opposingsides of the first bead-forming channel, and further wherein theinterior surface of the second bead-forming block comprises a thirdtrack surface and a fourth track surface on opposing sides of the secondbead-forming channel.
 6. The bead-making apparatus of claim 5, whereinthe first bead-forming block and the second bead-forming block areslidably engaged with each other based on coupling the first tracksurface with the third track surface and the second track surface withthe fourth track surface.
 7. The bead-making apparatus of claim 6,wherein upon coupling the first track surface with the third tracksurface and coupling the second track surface with the fourth tracksurface, the first bead-forming channel is adjacent to the secondbead-forming channel.
 8. A bead-forming kit comprising: an upperbead-forming block having an interior portion comprising an upper blockguide, a first track surface, an upper bead-forming channel, and asecond track surface oriented in a direction of a first axis; a lowerbead-forming block having an interior portion comprising a lower blockguide, a third track surface, a lower bead-forming channel, and a fourthtrack surface oriented in a direction of the first axis, said lowerbead-forming channel corresponding to the upper bead-forming channel,wherein upon slidably engaging the interior portion of the upperbead-forming block with the interior portion of the lower bead-formingblock, the upper block guide is adjacent the fourth track surface andthe lower block guide is adjacent the second track surface; and anintegrated measuring feature coupled to at least one of the upperbead-forming block and the lower bead-forming block, said integratedmeasuring feature comprising an internal volume for measuring an amountof modeling compound for forming a bead between the upper bead-formingchannel and the lower bead-forming channel.
 9. The bead-forming kit ofclaim 8, wherein the upper bead-forming channel is recessed from thefirst track surface and the second track surface at a first bead-formingchannel depth, and further wherein the lower bead-forming channel isrecessed from the third track surface and the fourth track surface at asecond bead-forming channel depth.
 10. The bead-forming kit of claim 8,wherein based on orientation of the upper block guide adjacent thefourth track surface and the lower block guide adjacent the second tracksurface, the upper bead-forming block and the lower bead-forming blockare restricted from travel in a direction of a second axis perpendicularto the first axis during translation of the upper bead-forming block andthe lower bead-forming block along the first axis.
 11. The bead-formingkit of claim 8, wherein the integrated measuring feature is configuredto measure a threshold amount of modeling compound for forming a beadbetween the upper bead-forming channel and the lower bead-formingchannel.
 12. The bead-forming kit of claim 8, wherein the measuredthreshold amount of modeling compound is configured to contact the upperbead-forming channel and the lower bead-forming channel duringtranslation of the upper bead-forming block and the lower bead-formingblock.
 13. The bead-forming kit of claim 8, wherein slidably engagingthe interior portion of the upper bead-forming block with the interiorportion of the lower bead-forming block comprises translating the upperand lower bead-forming blocks with respect to each other along adirection of motion.
 14. The bead-forming kit of claim 13, wherein theupper bead-forming channel is aligned with the lower bead-formingchannel upon slidably engaging the interior portion of the upperbead-forming block with the interior portion of the lower bead-formingblock.
 15. The bead-forming kit of claim 14, wherein the upperbead-forming channel comprises an upper channel shape oriented in adirection of the first axis, and the lower bead-forming channelcomprises a lower channel shape oriented in a direction of the firstaxis, said upper channel shape being a mirror image of the lower channelshape.
 16. The bead-forming kit of claim 8, wherein the kit furthercomprises an outer coating for applying to an outer surface of a beadformed between the upper and lower bead-forming blocks.
 17. A method forforming a bead between two bead-forming blocks, said method comprising:measuring an amount of modeling compound with a measuring featurecoupled to one of a first guide block and a second guide block;depositing the measured amount of modeling compound between a firstbead-forming channel of the first guide block and a second bead-formingchannel of the second guide block; and translating an interior surfaceof the first guide block with respect to an interior surface of thesecond guide block such that the measured amount of modeling compound ismanipulated between the first bead-forming channel and the secondbead-forming channel to provide a molded bead corresponding to a firstchannel shape of the first bead-forming channel and a second channelshape of the second bead-forming channel.
 18. The method of claim 17,wherein the measuring feature comprises an internal volume correspondingto the first channel shape and the second channel shape, wherein thefirst channel shape is a mirror image of the second channel shape. 19.The method of claim 17, wherein translating the first guide block withrespect to the second guide block comprises engaging a first tracksurface of the first guide block with a fourth track surface of thesecond guide block, and engaging a second track surface of the firstguide block with a third track surface of the second guide block. 20.The method of claim 17 further comprising applying a multicomponentouter coating to the molded bead.